Mutations in the Saccharomyces cerevisiae CDC1 gene affect double-strand-break-induced intrachromosomal recombination

To isolate Saccharomyces cerevisiae mutants defective in recombinational DNA repair, we constructed a strain that contains duplicated ura3 alleles that flank LEU2 and ADE5 genes at the ura3 locus on chromosome V. When a HO endonuclease cleavage site is located within one of the ura3 alleles, Ura+ recombination is increased over 100-fold in wild-type strains following HO induction from the GAL1, 10 promoter. This strain was used to screen for mutants that exhibited reduced levels of HO-induced intrachromosomal recombination without significantly affecting the spontaneous frequency of Ura+ recombination. One of the mutations isolated through this screen was found to affect the essential gene CDC1. This mutation, cdc1-100, completely eliminated HO-induced Ura+ recombination yet maintained both spontaneous preinduced recombination levels and cell viability, cdc1-100 mutants were moderately sensitive to killing by methyl methanesulfonate and gamma irradiation. The effect of the cdc1-100 mutation on recombinational double-strand break repair indicates that a recombinationally silent mechanism other than sister chromatid exchange was responsible for the efficient repair of DNA double-strand breaks.

Use of an oriented peptide library to determine the optimal substrates of protein kinases

BACKGROUND

Phosphorylation by protein kinases is an important general mechanism for controlling intracellular processes, and plays an essential part in the signal transduction pathways that regulate cell growth in response to extracellular signals. A great number of protein kinases have been discovered, and the identification of their biological targets is still a very active research area. Protein kinases must have the appropriate substrate specificity to ensure that signals are transmitted correctly. Previous studies have demonstrated the importance of primary sequences within substrate proteins in determining protein kinase specificity, but efficient ways of identifying these sequences are lacking.

RESULTS

We have developed a new technique for determining the substrate specificity of protein kinases, using an oriented library of more than 2.5 billion peptide substrates. In this approach, the consensus sequence of optimal substrates is determined by sequencing the mixture of products generated during a brief reaction with the kinase of interest. The optimal substrate predicted for cAMP-dependent protein kinase (PKA) by this technique is consistent with the sequences of known PKA substrates. The optimal sequences predicted for cyclin-dependent kinases (CDKs) cyclin B-Cdc2 and cyclin A-CDK2 also agree well with sites thought to be phosphorylated in vivo by these kinases. In addition, we determined the optimal substrate for SLK1, a homologue of the STE20 protein serine kinase of hitherto unknown substrate specificity. We also discuss a model incorporating the optimal cyclin B-Cdc2 substrate into the known crystal structure of this kinase.

CONCLUSIONS

Using the new technique we have developed, the sequence specificity of protein kinases can rapidly be predicted and, from this information, potential targets of the kinases can be identified.

A member of a novel family of yeast ‘zn-finger’ proteins mediates the transition from stationary phase to cell proliferation

The cloning and molecular characterization of the GCS1 gene from the budding yeast Saccharomyces cerevisiae show that stationary phase is in fact a unique developmental state, with requirements to resume cell proliferation that can be distinct from those for maintenance of proliferation. Deletion of the GCS1 gene products a novel phenotype: stationary-phase mutant cells do not resume proliferation at a restrictive temperature of 15 degrees C, but mutant cells lacking Gcs1p that are proliferating at the permissive temperature of 29 degrees C continue to proliferate after transfer to 15 degrees C as long as nutrients are available. The GCS1 gene sequence predicts a 39 kDa polypeptide with a novel 'Zn-finger' motif. A point mutation within the finger motif produces a phenotype that mimics that of deletion of the GCS1 gene, showing that the finger motif is essential for full Gcs1p activity. Gcs1p and the products of two newly identified genes, SPS18 and GLO3, constitute a family of novel Zn-finger proteins.

Budding and fission yeast casein kinase I isoforms have dual-specificity protein kinase activity

We have examined the activity and substrate specificity of the Saccharomyces cerevisiae Hrr25p and the Schizosaccharomyces pombe Hhp1, Hhp2, and Cki1 protein kinase isoforms. These four gene products are isotypes of casein kinase I (CKI), and the sequence of these protein kinases predicts that they are protein serine/threonine kinases. However, each of these four protein kinases, when expressed in Escherichia coli in an active form, was recognized by anti-phosphotyrosine antibodies. Phosphoamino acid analysis of 32P-labeled proteins showed phosphorylation on serine, threonine, and tyrosine residues. The E. coli produced forms of Hhp1, Hhp2, and Cki1 were autophosphorylated on tyrosine, and both Hhp1 and Hhp2 were capable of phosphorylating the tyrosine-protein kinase synthetic peptide substrate polymer poly-E4Y1. Immune complex protein kinases assays from S. pombe cells showed that Hhp1-containing precipitates were associated with a protein-tyrosine kinase activity, and the Hhp1 present in these immunoprecipitates was phosphorylated on tyrosine residues. Although dephosphorylation of Hhp1 and Hhp2 by Ser/Thr phosphatase had little effect on the specific activity, tyrosine dephosphorylation of Hhp1 and Hhp2 caused a 1.8-to 3.1-fold increase in the Km for poly-E4Y1 and casein. These data demonstrate that four different CKI isoforms from two different yeasts are capable of protein-tyrosine kinase activity and encode dual-specificity protein kinases.

Characterization of two protein kinases from Schizosaccharomyces pombe involved in the regulation of DNA repair

We have identified two novel genes designated hhp1+ and hhp2+ in the fission yeast Schizosaccharomyces pombe. The hhp1+ and hhp2+ genes encode two closely related protein kinases that share significant sequence identities with Hrr25p from Saccharomyces cerevisiae. Characterization of strains harboring single and double mutations in the hhp+ genes reveals DNA repair defects in these cells. Schizosaccharomyces pombe strains lacking either or both Hhp activities reveal differences in their ability to withstand DNA lesions caused by either methyl methanesulfonate (MMS) or gamma-rays which correlate with their ability to repair DNA strand breaks caused by these agents. We suggest that Hhp1 and Hhp2 are involved in the regulation of distinct and overlapping DNA repair pathways in S. pombe.

The budding yeast HRR25 gene product is a casein kinase I isoform

The Saccharomyces cerevisiae HRR25 gene was identified as a regulator of DNA strand-break repair. HRR25 encodes a protein kinase that is closely related to bovine casein kinase I (CKI). CKI is a ubiquitous multipotential protein kinase. Rabbit polyclonal antibodies that recognize and immunoprecipitate Hrr25p have been generated and an immune complex protein kinase assay has been developed. The reaction depends upon HRR25 and shows that Hrr25p uses casein as a substrate. The identity between Hrr25p and bovine CKI suggests that Hrr25p is a yeast isoform of the CKI family and that CKIs may play a role in regulating DNA metabolism.

Are casein kinases the assistant coaches for DNA metabolism?

A cell can be thought of as a well-coached sports team. To win, it needs superstar players with specialized tasks, but it also needs team players who can be relied on to maintain constant performance. Growth factor receptors or transcriptional activators might be considered to be the cell's superstars, whereas ribosomes could be considered team players that faithfully carry out directions from mRNA. The team also needs a head coach for overall direction and assistant coaches to direct the basic skills. The assistant coaches should ensure that basic cellular functions proceed correctly and that the cell responds to specific stimuli. Since almost every phosphorylatable protein is modified by several protein kinases, protein kinases like casein kinases I and II might be the assistant coaches of cellular regulation.

A mouse cdc25 homolog is differentially and developmentally expressed

The timing and activation of the p34cdc2 kinase in mammals is associated with dephosphorylation of phosphotyrosine and phosphothreonine residues on the p34cdc2 kinase. For fission yeast, the timing of mitosis is regulated by cyclic accumulation of cdc25, which promotes dephosphorylation of p34cdc2 and concomitant protein kinase activation. We report the identification and characterization of a structural and functional mouse homolog, Cdc25M2, of the cdc25 phosphatase. Cdc25M2 shows high sequence identity to the previously reported human homolog cdc25Hu2. Cdc25M2 can functionally complement for a Schizosaccharomyces pombe cdc25ts mutation, and when expressed in Escherichia coli and purified, Cdc25M2 is an active phosphatase. cdc25M2 mRNA shows variation in expression in different tissues in the mouse embryo and is expressed in a developmental and cell-cycle-dependent fashion. We suggest that the expression and accumulation of the cdc25 mitotic inducer may play a critical role in the regulation of mouse development.

Rescue of end fragments of yeast artificial chromosomes by homologous recombination in yeast

Yeast artificial chromosomes (YACs) provide a powerful tool for the isolation and mapping of large regions of mammalian chromosomes. We developed a rapid and efficient method for the isolation of DNA fragments representing the extreme ends of YAC clones by the insertion of a rescue plasmid into the YAC vector by homologous recombination. Two rescue vectors were constructed containing a yeast LYS2 selectable gene, a bacterial origin of replication, an antibiotic resistance gene, a polylinker containing multiple restriction sites, and a fragment homologous to one arm of the pYAC4 vector. The 'end-cloning' procedure involves transformation of the rescue vector into yeast cells carrying a YAC clone, followed by preparation of yeast DNA and transformation into bacterial cells. The resulting plasmids carry end-specific DNA fragments up to 20 kb in length, which are suitable for use as hybridization probes, as templates for direct DNA sequencing, and as probes for mapping by fluorescence in situ hybridization. These vectors are suitable for the rescue of end-clones from any YAC constructed using a pYAC-derived vector. We demonstrate the utility of these plasmids by rescuing YAC-end fragments from a human YAC library.

Genetically identified protein kinases in yeast. II: DNA metabolism and meiosis

Genetic analysis of protein kinases in Saccharomyces cerevisiae has revealed protein phosphorylation as a key regulatory mechanism both in the mitotic cell cycle and in meiosis. This article reviews genetically identified protein kinases that are associated with DNA metabolism and the meiotic pathway.

HRR25, a putative protein kinase from budding yeast: association with repair of damaged DNA

In simple eukaryotes, protein kinases regulate mitotic and meiotic cell cycles, the response to polypeptide pheromones, and the initiation of nuclear DNA synthesis. The protein HRR25 from the budding yeast Saccharomyces cerevisiae was defined by the mutation hrr25-1. This mutation resulted in sensitivity to continuous expression of the HO double-strand endonuclease, to methyl methanesulfonate, and to x-irradiation. Homozygotes of hrr25-1 were unable to sporulate and disruption and deletion of HRR25 interfered with mitotic and meiotic cell division. Sequence analysis revealed two distinctive regions in the protein. The NH2-terminus of HRR25 contains the hallmark features of protein kinases, whereas the COOH-terminus is rich in proline and glutamine. Mutations in HRR25 at conserved residues found in all protein kinases inactivated the gene, and these mutants exhibited the hrr25 null phenotypes. Taken together, the hrr25 mutant phenotypes and the features of the gene product indicate that HRR25 is a distinctive member of the protein kinase superfamily.

Genetically identified protein kinases in yeast. I: Transcription, translation, transport and mating

Studies from a wide array of different fields using Saccharomyces cerevisiae as an experimental organism have uncovered protein phosphorylation as a recurrent theme in the regulation of diverse cellular activities. Protein kinases in yeast regulate a variety of processes; this article discusses several genetically identified protein kinases and the roles that these kinases play in cell growth and development.

A Tn3 derivative that can be used to make short in-frame insertions within genes

A Tn3 derivative was constructed to make small in-frame insertions within genes. The transposon contains the URA3 gene, the tetA gene, a truncated lacZ, and phage P1 loxP recombination sites at either end. Insertions that have fused lacZ to an open reading frame are lac+ because they express the truncated lacZ. In the presence of the phage P1 cyclization recombinase cre, the transposon can delete the URA3, tetA, and lacZ genes between the two loxP sites. The remaining short imperfect palindrome contains the ends of Tn3 and a loxP site and does not contain a translational termination codon in the correct reading frame. We have analyzed several insertions within the yeast HO gene. Several insertions inactivate HO and prohibit initiation of mating-type switching. In contrast, an epitope inserted in the central portion encodes a functional HO endonuclease.

Site-directed, recombination-mediated mutagenesis of a complex gene locus

We have generated a site-specific 17 bp insertion within a 38 kb chick globin gene cluster by employing the recombination abilities of Saccharomyces cerevisiae. This gene cluster contains four beta-type globin genes which share a high degree of sequence homology. In this procedure, a small fragment of beta A-globin DNA containing a 17 bp insertion is subcloned into a URA3-based yeast integrating vector (YIp). This mutated globin subclone is introduced into cells that carry the 38 kb globin cluster clone on a single-copy, circular vector derived from a yeast artificial chromosome (YAC). Insertion of the 17 bp oligomer is achieved by targeted integration of the Ylp subclone. The recombinant contains the normal beta A-globin gene, the mutant gene and Ylp vector sequences between the two copies. Excision of the vector sequences and one copy of the duplicated globin sequences by homologous recombination is required for cell survival when exposed to the selective agent 5-fluoroorotic acid, which is toxic to ura+ yeast cells. Depending upon the point of the cross-over, a ura- yeast cell bearing either a wild-type globin gene or a 17 bp insertion mutation will result. By restriction mapping and in vitro transcription analysis, the beta A-globin gene containing the 17 bp insert has no nonspecific mutations generated during the recombination and selection procedures. Specific mutations of regulatory regions, including protein-DNA binding sites, can be accurately targeted within extensive DNA clones by this method.

The mouse c-rel protein has an N-terminal regulatory domain and a C-terminal transcriptional transactivation domain

We have shown that the murine c-rel protein can act as a transcriptional transactivator in both yeast and mammalian cells. Fusion proteins generated by linking rel sequences to the DNA-binding domain of the yeast transcriptional activator GAL4 activate transcription from a reporter gene linked in cis to a GAL4 binding site. The full-length mouse c-rel protein (588 amino acids long) is a poor transactivator; however, the C-terminal portion of the protein between amino acid residues 403 to 568 is a potent transcriptional transactivator. Deletion of the N-terminal half of the c-rel protein augments its transactivation function. We propose that c-rel protein has an N-terminal regulatory domain and a C-terminal transactivation domain which together modulate its function as a transcriptional transactivator.

Genetic control of RNA polymerase I-stimulated recombination in yeast

We examined the genetic control of the activity of HOT1, a cis-acting recombination-stimulatory sequence of Saccharomyces cerevisiae. Mutations in RAD1 and RAD52 decrease the ability of HOT1 to stimulate intrachromosomal recombination while mutations in RAD4 and RAD50 do not affect HOT1 activity. In rad1 delta strains, the stimulation of excisive recombination by HOT1 is decreased while the rate of gene replacement is not affected. In rad52-8 strains the ability of HOT1 to stimulate both excisive recombination and gene replacement is decreased. All of the recombinants in the rad52-8 strains that would be categorized as gene replacements based on their phenotype are diploids apparently derived by endomitosis and excisive recombination. Studies on rad1 delta rad52-8 strains show that these mutations interact synergistically in the presence or absence of HOT1, resulting in low levels of recombination. The rate of gene replacement but not excisive recombination is stimulated by HOT1 in rad1 delta rad52-8 strains. Taken together, the results show that HOT1 stimulates exchange using multiple recombination pathways. Some of the activity of HOT1 is RAD1-dependent, some is RAD52-dependent, and some requires either RAD1 or RAD52 as suggested by the synergistic interaction found in double mutant strains. There is also a component of HOT1 activity that is independent of both RAD1 and RAD52.

Double-strand breaks stimulate alternative mechanisms of recombination repair

To test the double-strand break repair model, we used HO nuclease to introduce double-strand breaks at several sites along a yeast chromosome containing duplicated DNA. Depending on the configuration of the double-strand break and recombining markers, different spectra of recombinant products were observed. Different repair kinetics and recombinant products were observed when a double-strand break was introduced in unique or duplicated DNA. The results of this study suggest that double-strand breaks in yeast stimulate recombination by several mechanisms, and we propose an alternative mechanism for double-strand break-induced gene conversion that does not depend on direct participation of the broken ends.

Lid lysates: an economical and rapid method for plasmid analysis

A method for analyzing bacteria containing recombinant plasmids is described. It allows inexpensive and rapid manipulation and screening of a large number of clones without the need for extensive laboratory equipment.

A reexamination of the role of the RAD52 gene in spontaneous mitotic recombination

The RAD52 gene is required for much of the recombination that occurs in Saccharomyces cerevisiae. One of the two commonly utilized mutant alleles, rad52-2, increases rather than reduces mitotic recombination, yet in other respects appears to be a typical rad52 mutant allele. This raises the question as to whether RAD52 is really necessary for mitotic recombination. Analysis of a deletion/insertion allele created in vitro indicates that the null mutant phenotype is indeed a deficiency in mitotic recombination, especially in gene conversion. The data also indicate that RAD52 is required for crossing-over between at least some chromosomes. Finally, examination of the behavior of a replicating plasmid in rad52-1 strains indicates that the frequency of plasmid integration is substantially reduced from that in wild type, a conclusion consistent with a role for RAD52 in reciprocal crossing-over. Analysis of recombinants arising in rad52-2 strains suggests that this allele may result in the increased activity of a RAD52-independent recombinational pathway.

Spontaneous mitotic recombination in yeast: the hyper-recombinational rem1 mutations are alleles of the RAD3 gene

The RAD3 gene of Saccharomyces cerevisiae is required for UV excision-repair and is essential for cell viability. We have identified the rem1 mutations (enhanced spontaneous mitotic recombination and mutation) of Saccharomyces cerevisiae as alleles of RAD3 by genetic mapping, complementation with the cloned wild-type gene, and DNA hybridization. The high levels of spontaneous mitotic gene conversion, crossing over, and mutation conferred upon cells by the rem1 mutations are distinct from the effects of all other alleles of RAD3. We present preliminary data on the localization of the rem1 mutations within the RAD3 gene. The interaction of the rem1 mutant alleles with a number of radiation-sensitive mutations is also different than the interactions reported for previously described (UV-sensitive) alleles of RAD3. Double mutants of rem1 and a defect in the recombination-repair pathway are inviable, while double mutants containing UV-sensitive alleles of RAD3 are viable. The data presented here demonstrate that: (1) rem1 strains containing additional mutations in other excision-repair genes do not exhibit elevated gene conversion; (2) triple mutants containing rem1 and mutations in both excision-repair and recombination-repair are viable; (3) such triple mutants containing rad52 have reduced levels of gene conversion but wild-type frequencies of crossing over. We have interpreted these observations in a model to explain the effects of rem1. Consistent with the predictions of the model, we find that the size of DNA from rem1 strains, as measured by neutral sucrose gradients, is smaller than wild type.

Hyper-mutation caused by the reml mutation in yeast is not dependent on error-prone or excision repair

The reml mutations of Saccharomyces cerevisiae confer a semi-dominant hyper-recombination/hyper-mutation phenotype. Neither reml mutant allele has any apparent meiotic affect. We have examined spontaneous mutation in reml-2 strains and demonstrate that the reml-2 mutation, like reml-1, confers an average 10-fold increase in reversion and forward mutation rates. Unlike certain yeast rad mutations with phenotypes similar to reml, strains containing reml are resistant to MMS and only slightly UV sensitive at very high doses. To understand the mutator phenotype of reml, we have used a double-mutant approach, combining the reml mutation with radiation-sensitive mutations affecting DNA repair. Double mutants of reml-2 and a mutation in the yeast error-prone repair group (rad6-1) or a mutation in excision repair (rad1-2 or rad4) maintain the hyper-mutation phenotype. Since mutation rates remain elevated in these double-mutant strains, it appears as if the mutations which occur in the presence of reml resemble spontaneous mutation since they do not require the action of a repair system.

Excision repair functions in Saccharomyces cerevisiae recognize and repair methylation of adenine by the Escherichia coli dam gene

Unlike the DNA of higher eucaryotes, the DNA of Saccharomyces cerevisiae (bakers' yeast) is not methylated. Introduction of the Escherichia coli dam gene into yeast cells results in methylation of the N-6 position of adenine. The UV excision repair system of yeast cells specifically responds to the methylation, suggesting that it is capable of recognizing modifications which do not lead to major helix distortion. The UV repair functions examined in this report are involved in the incision step of pyrimidine dimer repair. These observations may have relevance to the rearrangements and recombination events observed when yeast or higher eucaryotic cells are transformed or transfected with DNA grown in E. coli.

Properties of spontaneous mitotic recombination occurring in the presence of the rad52-1 mutation of Saccharomyces cerevisiae

All major recombination pathways in the yeastSaccharomyces cerevisiaerequire theRAD52gene product. We have examined the effect of therad52-1mutation on spontaneous mitotic recombination between heteroalleles, and found that prototrophs are produced at frequencies significantly above reversion. This residual recombination occurs at a relatively uniform level at all of the loci examined. To help understand the role thatRAD52plays in mitotic recombination, we examined recombination between all pairwise combinations of six mutant alleles of theLYS2gene. Therad52-1mutation decreased the variation in amount of recombination between the various pairwise combinations as well as lowering the overall frequency of recombination. The reduced variation results in a different pattern of recombination inrad52-1cells than in wild type. One interpretation of these results is that theRAD52gene product, directly or indirectly, plays a role in the formation or the resolution of mismatches in heteroduplex DNA.

Expression of the Escherichia coli dam methylase in Saccharomyces cerevisiae: effect of in vivo adenine methylation on genetic recombination and mutation

The Escherichia coli DNA adenine methylase (dam) gene has been introduced into Saccharomyces cerevisiae on a yeast-E. coli shuttle vector. Sau3AI, MboI, and DpnI restriction enzyme digests and Southern hybridization analysis indicated that the dam gene is expressed in yeast cells and methylates GATC sequences. Analysis of digests of total genomic DNA indicated that some GATC sites are not sensitive to methylation. The failure to methylate may reflect an inaccessibility to the methylase due to chromosome structure. The effects of this in vivo methylation on the processes of recombination and mutation in mitotic cells were determined. A small but definite general increase was found in the frequency of mitotic recombination. A similar increase was observed for reversion of some auxotrophic markers; other markers demonstrated a small decrease in mutation frequency. The effects on mutation appear to be locus (or allele) specific. Recombination in meiotic cells was measured and was not detectably altered by the presence of 6-methyladenine in GATC sequences.